JP2004516703A - Transversal mode coupled resonator filter - Google Patents

Abstract

The present invention relates to a transversal coupled resonator filter based on acoustic surface waves.
SUMMARY OF THE INVENTION It is an object of the present invention to improve a resonator filter so as to reduce the insertion attenuation of a filter, particularly the attenuation due to cascade. In this resonator filter, a plurality of one-port resonator structures (2; 3) are sequentially arranged on a substrate (1), and this structure includes two strip reflectors (22, 23; 32, 33). ) And interdigital transducers (21; 31), and commonly form a waveguide for acoustic surface waves.
The problem is that for at least one one-port resonator structure (2; 3), the ratio of the electrode finger width to the spacing between the electrode finger centers (214; 215) and the reflective strips (221, 231; 321, 331). ) And the spacing between the centers of the reflective strips (224, 225; 234, 235) is solved by making them different from other one-port resonator structures.
The invention is particularly applicable to resonators for bandpass filters and oscillators having a relative bandwidth on the order of 0.1%.

Description

[0001]
TECHNICAL FIELD The present invention relates to electronic device technology / electronic circuit technology. Objects of advantageous application are acoustic surface wave-based modules, such as bandpass filters with relative bandwidths on the order of 0.1% and resonators for oscillators.
[0002]
2. Description of the Related Art There is known a transversal mode coupled resonator filter in which a plurality of one-port resonator structures are sequentially arranged on a piezoelectric substrate. The one-port resonator structure has a flat cavity and two strip reflectors whose reflective strips are shorted by shorting strips and an interdigital transducer located in the flat cavity. Made up of Here, in each one-port resonator structure, the strip region of the strip reflector or the electrode finger region of the interdigital transducer forms a waveguide for acoustic surface waves together with the short-circuit strip or the collecting electrode, and The detector structures are interconnected for a waveguide effect.
[0003]
In the special case (DE-A-197 44 948), two one-port resonator structures, called waveguide tracks, form two separate waveguide tracks without transducers. Are coupled through. Otherwise, the outer metallization, which is uniformly metallized, has different widths for the strips extending in the direction of the electrode fingers of the transducer, further dividing the gaps present between them. This division is transferred to adjust the phase velocity at the outer collector. The outer collector is located between the grating region, ie, the waveguide track, and the free region. No wave excitation occurs in this region. The electrode fingers and reflective strips of all transducers have equal width. This is also true for the gap between the electrode fingers of the transducer and the reflective strip.
[0004]
In the most widely extended special case, it consists of two one-port resonator structures (M. Tanaka, T. Morita, K. Ono & Y. Nakazawa, "Narrow bandpass filter using double-mode SAW"). Resonators on quarz ", 38th Annual Frequency Control Symposium 1984, pp. 286-293 [1]). The two transducers driven as filter inputs and outputs have a common collector electrode, which is connected to ground potential. In most cases, two identical filters of this kind are connected in a cascade.
[0005]
The disadvantage in these cases is that the amount of attenuation due to cascading, ie, the amount of insertion attenuation in the filter, becomes very large.
[0006]
DESCRIPTION OF THE INVENTION It is an object of the invention to modify a transversal mode-coupled resonator filter of the type mentioned at the outset and to reduce the insertion attenuation of the filter (in particular the attenuation due to cascading).
[0007]
This object is achieved according to the present invention by constructing a transversal mode coupled resonator filter according to the present invention.
[0008]
The resonator filter of the present invention has at least one one-port resonator structure in which the ratio of the width of the electrode finger to the distance between the centers of the electrode fingers and the ratio of the width of the reflection strip to the distance between the centers of the reflection strips are different. And a one-port resonator structure.
[0009]
The propagation speed of the acoustic surface wave depends in particular on the ratio of the electrode finger width to the distance between the centers of the electrode fingers, and the ratio of the width of the reflective strip to the distance between the centers of the reflective strips. Name. The presence of a plurality of one-port resonator structures having different metallization ratios means that the propagation velocities at the electrode finger grid and the strip grid of each one-port resonator structure are different from each other. For this reason, the resonator filter can be designed so that the one-port resonator structure having the coupling transducer has a different propagation speed from the other one-port resonator structures. A coupled transducer is here a transducer of various filters which is directly interconnected. This is the case, for example, for a filter cascade in which the output transducer of the first filter and the input transducer of the second filter are connected. When two similar filters are cascaded, a high energy density is formed around the low or high frequency resonance of the coupled transducer. This increases the actual guided value of the coupling transducer, while the capacitance remains unchanged.
[0010]
Therefore, the effective coupling coefficient is increased. This is a precondition for reducing the amount of insertion attenuation caused by cascading. The high effective coupling coefficient increases the degree to which low or high frequency resonances due to cascading can be split.
[0011]
The present invention can be advantageously configured as follows.
[0012]
Advantageously, the transducers or strip reflectors of adjacent one-port resonator structures form a common collector or shorting strip.
[0013]
A one-port resonator in which the ratio of the width of the electrode finger to the distance between the centers of the electrode fingers, and the ratio of the width of the reflective strip to the distance between the centers of the reflective strips are different from other one-port resonator structures. The structures differ from one another by the spacing between the centers of the electrode fingers and the spacing of the centers of the reflective strips. Further, the center distance between the electrode fingers and the center distance between the reflection strips may be equal in all the one-port resonator structures.
[0014]
The number of one-port resonator structures is two. In this case, the apertures of the transducer and the reflector may be made equal by the two one-port resonator structures, or may be made different.
[0015]
It is particularly advantageous if the number of one-port resonator structures is greater than two. Thereby, two groups can be formed by the one-port resonator structure. Here, all the transducers of one group are connected in parallel with one another, one group being input transducers and the other group being output transducers.
[0016]
More preferably, a gap is provided between adjacent one-port resonator structures, the gap being filled by a reflective strip at the same potential.
[0017]
The transducers in the at least one one-port resonator structure have different electrode finger polarities than the other transducers.
[0018]
With particular preference, two like filters form a filter cascade, the same group being used as a coupling transducer in the two filters, wherein the coupling transducer is connected to a different group of filters. Means a group. In this case, it is advantageous if the groups forming the respective coupling transducers consist of one-port resonator structures having the same electrode finger width, the same reflection strip width and the same gap width. The ratio of the width of the electrode fingers to the spacing between the centers of the electrode fingers, and the ratio of the width of the reflecting strips to the spacing between the centers of the reflecting strips in the group forming the coupling transducer, is the same as that of all other one-port resonator structures. It can be larger or smaller.
[0019]
BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a basic circuit diagram showing a design of an embodiment of a transversal mode-coupled resonator filter of the present invention described below.
[0020]
BEST MODE FOR CARRYING OUT THE INVENTION The present invention will be described in detail below based on embodiments shown in the accompanying drawings.
[0021]
Two one-port resonator structures 2 and 3 are arranged side by side on a piezoelectric substrate 1. These structures have reflectors 22, 23 and 32, 33 in the same order. An interdigital transducer 21 is arranged between the reflectors 22 and 23, and an interdigital transducer 31 is arranged between the reflectors 32 and 33. The transducer 21 includes collecting electrodes 212 and 213 and an electrode finger 211. The transducer 31 forms a common collecting electrode 213 together with the transducer 21, and further includes a collecting electrode 312 and an electrode finger 311. The reflector 22 includes a reflection strip 221 and short-circuit strips 222 and 223, and the reflector 23 includes a reflection strip 231 and short-circuit strips 232 and 233. The reflector 32 forms a common shorting strip 223 with the reflector 22 and further comprises a reflecting strip 321 and a shorting strip 322. Similarly, the reflector 33 forms a common shorting strip 233 with the reflector 23 and further comprises a reflecting strip 331 and a shorting strip 332.
[0022]
The center line of the electrode finger 211 of the transducer 21 and the center line of the electrode finger 311 of the transducer 31 are mutually extended lines, and form a common center line 215. The same applies to the common center line 214. The spacing 216 between the common center lines 214, 215 is therefore equal in the two transducers 21, 31. However, the width of the electrode finger 211 of the transducer 21 and the width of the electrode finger 311 of the transducer 31 are different from each other.
[0023]
The center line of the reflection strip 221 of the strip reflector 22 and the center line of the reflection strip 321 of the strip reflector 32 are mutually extended lines and form a common center line 224. The same applies to the common center line 225. Thus, the spacing 216 between the common centerlines 224, 225 is equal in the two strip reflectors 22, 32. However, the width of the reflection strip 221 of the strip reflector 22 and the width of the reflection strip 321 of the strip reflector 32 are different from each other. The same applies to the strip reflectors 23, 33.
[0024]
The center line of the reflection strip 231 of the strip reflector 23 and the center line of the reflection strip 331 of the strip reflector 33 are mutually extended lines, and form a common center line 235. The same applies to the common center line 234. The spacing 236 between the common center lines 234, 235 is therefore equal in the two strip reflectors 23, 33. However, the width of the reflection strip 231 of the strip reflector 23 and the width of the reflection strip 331 of the strip reflector 33 are different from each other.
[0025]
The shorting strips 222, 232; 223, 233; 322, 332 of each strip reflector are extensions of the collectors 212; 213; 312 in the same order. The shorting strips 223, 233 together with the collector 213 form a coupling strip. Each one-port resonator structure is a waveguide for acoustic surface waves that guides waves in the electrode finger region and the reflective strip region. The coupling strip 4 controls the coupling between the two waveguides.
[0026]
The transducer 21 is connected to the filter input 5. The transducer 31 is connected to the filter output 6. The reflectors 22, 23, 32, 33 and the common collector electrode 213 are connected to the ground potential 7.
[0027]
Due to the wide electrode fingers and the reflective strips of the one-port resonator structure 3, the propagation speed in the electrode finger grating and the strip grating here is lower than that in the one-port resonator structure 2. The profile of the waveguide mode is thus asymmetric, and the energy density of the wave and the resulting effective coupling coefficient are particularly large around the low-frequency resonance in the one-port resonator structure 3. A filter cascade is formed from two resonator filters, of which only one is shown in the figure. The filter cascade is formed by connecting the terminal 6 on the output side of the first filter and the terminal 6 on the input side of the second filter. With two resonator filters, transducer 31 is a coupled transducer. The high effective coupling coefficient at the coupling transducer reduces the amount of resonance attenuation at low frequencies due to cascading.
[Brief description of the drawings]
FIG.
FIG. 2 is a basic circuit diagram of a transversal mode coupling type resonator filter of the present invention.

Claims (15)

A plurality of one-port resonator structures (2; 3) are arranged side by side on a piezoelectric substrate (1),
The structure comprises two strip reflectors (22) having flat cavities and reflective strips (221, 231; 321, 331) shorted by shorting strips (222, 223; 232, 233; 322, 332). , 23; 32, 33) and an interdigital transducer (21; 31) arranged in a flat cavity,
In each one-port resonator structure (2; 3), the strip area of the strip reflector (22, 23; 32, 33) is the electrode finger area of the interdigital transducer (21; 31) and the short-circuit strip (222, 223; 232, 233; 322, 332) or collector electrodes (212; 213; 312) to form a waveguide for acoustic surface waves.
The one-port resonator structures (2; 3) are interconnected for a waveguide effect;
In a transversal mode coupled resonator filter based on acoustic surface waves,
In at least one one-port resonator structure (2; 3), the ratio of the electrode finger width to the spacing (216) between the electrode finger centers (214; 215), and the reflective strips (221, 231; 321; 331). ) And the spacing (226; 236) between the centers (224, 225; 234, 235) of the reflective strips are different from the other one-port resonator structures.
A transversal mode coupling type resonator filter characterized by the above-mentioned. Transducers (21; 31) or strip reflectors (22; 23; 32; 33) of adjacent one-port resonator structures (2; 3) share a common collector (213) or shorting strip (223; 233). The resonator filter according to claim 1, wherein The ratio of the electrode finger width to the spacing (216) between the electrode finger centers (214; 215), and the width of the reflective strips (221; 231; 321; 331) and the center of the reflective strips (224, 225; 234, 235). ) Is different from the other one-port resonator structure in the ratio of the spacing (226; 236) to the center of the electrode finger (214; 215). 2. The resonator filter according to claim 1, which differs from one another by the spacing between the reflection strips and the spacing (226; 236) of the center (224; 225, 234; 235) of the reflection strips (221, 231; 321; 331). The spacing (216) between the centers (214; 215) of the electrode fingers and the spacing (226; 236) between the centers (224, 225; 234, 235) of the reflective strips (221; 231; 321; 331) are all 1 The resonator filter according to claim 1, wherein the port resonator structures (2; 3) are equal. The resonator filter according to claim 1, wherein the number of the one-port resonator structures (2; 3) is two. 6. The resonator filter according to claim 5, wherein the apertures of the transducer (21; 31) and the reflector (22, 23; 32, 33) are equal in the two one-port resonator structures (2; 3). 6. The resonator filter according to claim 5, wherein the apertures of the transducer (21; 31) and the reflector (22, 23; 32, 33) are different for the two one-port resonator structures (2; 3). 2. Resonator filter according to claim 1, wherein the number of one-port resonator structures (2; 3) is greater than two. The one-port resonator structures (2; 3) form two groups, all the transducers of one group being connected in parallel with one another, one group being the input transducer and the other being the input transducer. 9. The resonator filter according to claim 8, wherein the groups of are resonators on the output side. 2. The resonator filter according to claim 1, wherein a gap is provided between adjacent one-port resonator structures (2; 3), the gap being filled by a reflective strip at the same potential. 2. The resonator filter according to claim 1, wherein the polarity of the electrode fingers of the transducer (21; 31) in the at least one one-port resonator structure is different from that of the other transducers. Two similar filters of claim 9 form a filter cascade, wherein the same group of two filters is used as a coupling transducer, wherein each of the coupling transducers is connected to one group of the other filter. The resonator filter according to claim 1, wherein the group is a group including a plurality of resonators. 13. The resonator filter according to claim 12, wherein the group forming each coupling transducer comprises a one-port resonator structure (2; 3) having an equal electrode finger width, an equal reflective strip width, and an equal gap width. The ratio of the electrode finger width to the spacing between the electrode finger centers (214; 215) in the group forming the coupling transducer, and the width of the reflective strips (221, 231; 321, 331) and the center of the reflective strips (224, 225). 14. The resonator filter according to claim 13, wherein the ratio to the spacing between (234, 235) is greater than that of all other one-port resonator structures (2; 3). The ratio of the electrode finger width to the spacing between the electrode finger centers (214; 215) in the group forming the coupling transducer, and the width of the reflective strips (221, 231; 321, 331) and the center of the reflective strips (224, 225). 14. The resonator according to claim 13, wherein the ratio to the spacing (224, 225; 234, 235) between them is smaller than that of all other one-port resonator structures (2; 3). filter.